KR100871122B1 - Antenna of magnetron - Google Patents

Abstract

An antenna of the magnetron is provided to reduce the generation of noise in the drive of magnetron by increasing the output of magnetron and positioning the antenna at the center of the exhaust pipe. An antenna of the magnetron comprises the A- room of the cylindrical shape blocking the outer leakage of harmonic; the A- ceramics in which it becomes the path which is equipped in the A- disappointment upper end and in which the high frequency energy is emitted to outside; the exhaust pipe(319) in which hollow is formed in the center while being equipped in the upper end of the A- ceramics; magnetron including the antenna(320) which is contacted with the top end portion virtualized exhaust pipe and outputs the high frequency oscillated in the cavity resonator.

Description

Antenna of magnetron {ANTENNA OF MAGNETRON}

1 is a plan view showing the structure of a conventional magnetron,

2 is a plan view showing the structure of the antenna of FIG.

3 is a plan view showing the structure of an antenna of a magnetron according to an embodiment of the present invention;

4 is a plan view showing the structure of an antenna of a magnetron according to another embodiment of the present invention;

5 is a plan view showing the structure of an antenna of a magnetron according to another embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

301: York 301a: upper yoke

301b: lower yoke 313: upper pole piece

314: lower pole piece 315: A-seal

316: F-room 320: antenna

The present invention relates to an antenna of a magnetron, and more particularly, by placing the antenna at the center of the exhaust pipe when the magnetron is manufactured, improving the output of the magnetron to increase efficiency and generating noise when driving the magnetron. It relates to an antenna of a magnetron that can be reduced.

1 is a perspective view showing the structure of a conventional magnetron, Figure 2 is a plan view showing the structure of the antenna of FIG.

As shown in these figures, the structure of a conventional magnetron includes a yoke 301 having a constant internal space formed by a combination of an upper yoke 301a and a lower yoke 301b, and a yoke 301 that is accommodated in an internal space. Of the upper magnet 321 and the lower magnet 322 and the upper magnet 321 and the lower magnet 322 fixedly coupled to the inner surface of the upper yoke 301a and the lower yoke 301b along the width direction of An anode cylinder 302 disposed in the space therebetween and generating high frequency energy, and an upper pole piece 313 and a lower pole piece 314 having a funnel shape disposed at upper and lower openings of the anode cylinder 302, respectively. And a cylindrical A-chamber 315 disposed above the upper pole piece 313 and blocking external leakage of five harmonics, and joined to an inner plate surface of the A-chamber 315 to prevent external leakage of three harmonics. It is configured to include a coaxial choke filter 330 to block.

The upper yoke 301a and the lower yoke 301b are coupled to form a rectangular cross section, and a cylindrical anode cylinder 302 is installed inside the yoke 301, and a high frequency inside the anode cylinder 302. A plurality of vanes 303 forming a cavity resonator are arranged radially toward the axial direction to induce the component.

Upper and lower pressure equalizing rings 304 and outer pressure equalizing rings 305 are alternately connected to upper and lower ends of the vane 303, respectively, to form an anode along with the anode cylinder 302.

On the central axis of the anode cylinder 302, a spirally wound filament 307 is formed to form a tip space of the vane 303 and a working space 306 of a predetermined interval, and the filament 307 is formed of tungsten and thorium oxide. The mixture is heated by the operating current supplied to the filament 307 to form a cathode which emits hot electrons.

A top shield 308 is fixed to the upper end of the filament 307 to block the emitted hot electrons from radiating upward, and an end shield 309 to block the radiated hot electrons from radiating downward in the lower part. Molybdenum center lead 310 is inserted into the through hole formed in the center portion of the end shield 309 and is bonded to the lower surface of the top shield 308, and the center lead 310 is fixed to the lower surface of the end shield 309. The upper ends of the side leads 311 made of molybdenum are bonded at intervals.

In addition, the upper and lower openings of the anode cylinder 302 are coupled to the upper pole piece 313 and the lower pole piece 314 of a funnel shape made of a magnetic material, and the upper and lower pole pieces of the upper pole piece 313 ( At the lower side of 314, cylindrical A-seal 315 and F-seal 316 are brazed to each other to prevent external leakage of the three harmonic components.

The upper magnet 321 and the lower magnet 322 are coupled to the upper side and the lower side of the anode cylinder 302 so as to be in contact with the inner side surface of the yoke 301, so that the upper pole piece 313 and the lower pole piece 314 and It is possible to form a magnetic field together.

The cooling fin 323 is provided between the inner circumferential surface of the yoke 301 and the outer circumferential surface of the anode cylinder 302, and the antenna is provided on the upper side of the A-ceramic 317 to protect the junction of the exhaust pipe 319. The cap 324 is covered.

The upper end of the A-chamber 315 is bent to the inside of the A-chamber 315 and is formed to extend a predetermined length downward along the height direction of the A-chamber to form a closed circuit, thereby bending to prevent external leakage of five harmonics. The part 315a is formed.

In addition, the A-ceramic 317 for outputting high frequency and the F-ceramic 318 for hot rolling are brazed at the upper side of the A-silk 315 and the lower side of the F-silk 316. An exhaust pipe 319 is joined to the upper side of the ceramic 317 by brazing, and an upper end of the exhaust pipe 319 is joined at the same time as the cutting to seal the inside of the anode cylinder 302 in a vacuum state.

An antenna 320 for outputting high frequency oscillated in the cavity resonator is installed inside the A-chamber 315, and the lower end of the antenna 320 is connected to the vane 303, and the upper end thereof is an exhaust pipe 319. It is fixed at the center of the upper surface of.

However, in the manufacture of the magnetron having such a configuration, as an end of the exhaust process for maintaining the magnetron in a high vacuum, the exhaust pipe 319 is cut using the tip-off machine as part of the tip-off process for vacuum sealing. , Since the two blades of the tip-off cutting the exhaust pipe 319 is a rounded knife, the exhaust pipe 319 and the antenna 320 are slightly lifted or the shape of the exhaust pipe 319 is pressed while the two blades close together. Due to the deformation, the position of the antenna 320 positioned at the center of the exhaust pipe 319 is changed to generate noise, thereby degrading the efficiency and output of the magnetron.

Accordingly, an object of the present invention is to provide an antenna of a magnetron that can increase the efficiency by increasing the output of the magnetron by placing the antenna at the center of the exhaust pipe when the magnetron is manufactured, and reduce the phenomenon in which noise is generated when the magnetron is driven. It is.

The object is, according to the present invention, a cylindrical A-thread for blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; A magnetron comprising an antenna extending from the inside of the A-chamber and having an upper end thereof in contact with the exhaust pipe and outputting a high frequency oscillated in the cavity resonator, wherein the antenna is connected to the A even when the upper end of the antenna is cut off. The upper part of the antenna being cut off so as to pass through the center of the seal, the A-ceramic and the exhaust pipe is thinner than the other lower part.

Here, the diameter of the upper portion of the antenna to be cut off is 0.5 to 0.6 times the diameter of the other lower portion, the upper portion is preferably connected in a tapered shape at the end of the lower portion.

In addition, the diameter of the upper portion of the antenna to be cut off is 0.3 times to 0.4 times the diameter of the other lower portion, the upper portion may be connected in a round shape at the end of the other lower portion.

In addition, a center holding member is further provided at an upper end of the antenna, wherein the center holding member is a cylindrical center holding guide formed such that its outer circumferential surface is in contact with the inner circumferential surface of the exhaust pipe.

In addition, it is effective to display the direction in which the upper portion of the antenna is cut off on the outer surface of the exhaust pipe so that the antenna can pass through the center of the A-sil, A-ceramic and exhaust pipe even when the upper end of the antenna is cut off.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

However, the same reference numerals are given to the same parts as in the conventional configuration, and detailed description thereof will be omitted.

3 is a plan view showing the structure of an antenna of a magnetron according to an embodiment of the present invention, Figure 4 is a plan view showing the structure of an antenna of a magnetron according to another embodiment of the present invention, Figure 5 is a view of the present invention 4 is a plan view illustrating a structure of an antenna of a magnetron according to another embodiment.

As shown in these figures, the antenna of the magnetron according to an embodiment of the present invention, the cylindrical A-chamber 315 to block the external leakage of harmonics, and is provided on the upper end of the A-chamber 315 A-ceramic 318, which is a passage through which high-frequency energy is discharged to the outside, an exhaust pipe 319 formed at the top of the A-ceramic 318 and having a hollow in the center thereof, and inside the A-seal 315 In the magnetron is extended and the upper end is in contact with the exhaust pipe 319 and comprises an antenna 320 for outputting a high frequency oscillated in the cavity resonator, the antenna 320 is the upper end of the antenna 320 even when cut off An upper portion 321 of the antenna 320 cut off to pass through the centers of the A-seal 315 and the A-ceramic 318 and the exhaust pipe 319 is thinner than the other portion 320.

In the antenna of the magnetron according to an exemplary embodiment of the present invention illustrated in FIG. 3, the diameter of the upper portion 321 of the antenna 320 to be cut off is lower than the other portion (that is, the lower portion formed relatively thicker than the upper portion, 322). The upper portion of the antenna 320 is cut off so as to reduce the impact after the cutoff to minimize deformation of the antenna 320 by reducing the impact after the cutoff. It is coupled to the end of the tapered shape.

 In the antenna of the magnetron according to another embodiment of the present invention illustrated in FIG. 4, the diameter of the upper portion 321 of the antenna 320 to be cut off is different from that of the other portion (lower portion 322 formed relatively thicker than the upper portion). It is formed to 0.3 times to 0.4 times the diameter, and the upper portion of the antenna 320, which is cut off to ensure reliability by reinforcing the weak part of the structure is coupled to the end of the other portion of the antenna 320 in a tapered shape. .

In the antenna of the magnetron according to still another embodiment of the present invention illustrated in FIG. 5, the antenna 320 may include the A-chamber 315, the A-ceramic 318, and the exhaust pipe even when the upper end of the antenna 320 is cut off. The upper portion 321 of the antenna 320 cut off so as to pass through the center of the 319 is formed thinner than the other portion 322, the end of the other portion formed thinly in contact with the inner peripheral surface of the exhaust pipe 319 The cylindrical center holding guide 323 having a diameter to be fixed is coupled.

In addition, the antenna 320 is disposed on the outer surface of the exhaust pipe 319 so that the antenna 320 can pass through the center of the A-chamber 315, the A-ceramic 318, and the exhaust pipe 319 even when the upper end of the antenna 320 is cut off. The direction in which the upper portion 321 of 320 is cut off is indicated.

With this configuration, in manufacturing the magnetron, the exhaust pipe 319 is inserted between the two round blades of the tip-off group at the time of tip-off, and the exhaust pipe 319 is pressed from both sides by closely contacting the round pipes. Since the end of the antenna 320 located inside the 319 does not deviate from the center of the exhaust pipe 319 by the above-described structure, it is possible to prevent a phenomenon in which the efficiency and output of the magnetron is lowered and to suppress the generation of noise.

As described above, according to the present invention, a plurality of vanes disposed radially toward the axial direction to induce a high frequency component to form a cavity resonator; A cylindrical A-silk installed above the vane and blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; A magnetron comprising an antenna extending from the inside of the A-chamber and having an upper end thereof in contact with the exhaust pipe and outputting a high frequency oscillated in the cavity resonator, wherein the antenna is connected to the vane; An extension part extending from a connection part and passing through the centers of the A-chamber and the A-ceramic and an output part provided at the end of the extension part and disposed at the center of the exhaust pipe are provided separately, thereby providing an antenna at the time of manufacturing the magnetron. By being located at the center of the exhaust pipe, the output of the magnetron is improved to increase efficiency, and there is an effect of reducing the phenomenon of noise generated when the magnetron is driven.

Claims (6)

delete A cylindrical A-thread for blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; In the magnetron comprising an antenna extending from the inside of the A-chamber and the upper end thereof is in contact with the exhaust pipe to output a high frequency oscillated in the cavity resonator, The upper portion of the antenna to be cut off is formed thinner than the lower portion so that the antenna can pass through the centers of the A-sil and A-ceramic and exhaust pipes even when the upper end of the antenna is cut off, The diameter of the upper portion of the antenna to be cut off is 0.5 to 0.6 times the diameter of the lower portion, the upper portion of the antenna of the magnetron, characterized in that connected to the lower portion in a tapered shape. A cylindrical A-thread for blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; In the magnetron comprising an antenna extending from the inside of the A-chamber and the upper end thereof is in contact with the exhaust pipe to output a high frequency oscillated in the cavity resonator, The upper portion of the antenna to be cut off is formed thinner than the lower portion so that the antenna can pass through the centers of the A-sil and A-ceramic and exhaust pipes even when the upper end of the antenna is cut off, The diameter of the upper portion of the antenna to be cut off is 0.3 times to 0.4 times the diameter of the lower portion, the upper portion of the antenna of the magnetron, characterized in that the lower portion and the longitudinal section is connected in a round shape. A cylindrical A-thread for blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; In the magnetron comprising an antenna extending from the inside of the A-chamber and the upper end thereof is in contact with the exhaust pipe to output a high frequency oscillated in the cavity resonator, The upper portion of the antenna to be cut off is formed thinner than the lower portion so that the antenna can pass through the centers of the A-sil and A-ceramic and exhaust pipes even when the upper end of the antenna is cut off, The antenna of the magnetron, characterized in that the upper end of the antenna further comprises a center holding member. The method of claim 4, wherein The center holding member is a magnetron antenna, characterized in that the outer peripheral surface of the cylinder-shaped center holding guide is formed to have a diameter in contact with the inner peripheral surface of the exhaust pipe. The method according to any one of claims 2 to 5, Magnetron, characterized in that the direction in which the upper portion of the antenna is cut off is displayed on the outer surface of the exhaust pipe so that the antenna passes through the center of the A-sil, A-ceramic and exhaust pipe even when the upper end of the antenna is cut off antenna.

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